Method and Apparatus for Communications of Data in a Communication System

ABSTRACT

A method and apparatus provides for efficient data rate control and power control processes by transmitting a primary and a secondary pilot channel associated with a data channel. The primary and secondary pilot channels are used for decoding the data. A ratio of power levels of the primary and secondary pilot channels is based on at least one of the data rate and payload size of the data channel. The power level of the primary pilot channel is maintained independent of at least one of data rate and payload size of the data channel. The power level of the secondary pilot channel may be adjusted based on at least one of data rate and payload size of the data channel.

CLAIM OF PRIORITY UNDER 35 U.S.C. §120

The present Application for Patent is a Continuation Application andclaims priority to patent application Ser. No. 10/454,038, entitled“Method and Apparatus for Communications of Data in a CommunicationSystem,” filed Jun. 3, 2003, and assigned to the assignee hereof andhereby expressly incorporated by reference herein.

FIELD

The present invention relates generally to the field of communications,and more particularly, to reverse link communications in a communicationsystem.

BACKGROUND

Reverse link transmissions may require transmission of a pilot signalfrom the mobile stations to allow for the receiver in the base stationto perform coherent multi-path combining and demodulation. Generally, tofind an optimum power level for the total transmission power level ofthe pilot channel and data channels, the power level for the pilotchannel is minimized while trying to achieve a decoding error rateperformance. For example, in a system commonly known as cdma2000 1x, forthe 9600 bit/s format at 1% frame error rate (FER), the optimum pilotchannel power level is found experimentally to be about 3.75 dB lowerthan the data channels power level. If the power level of the pilotchannel is increased much above such a defined level, the overalldecoding performance does not significantly improve, even though thetotal transmission power for pilot channel and the data channels ishigher. On the other hand, if the pilot channel power level is decreasedmuch below such a defined level, the data channels power level need tobe increased to achieve the same decoding error rate performance. Insuch a case, the total power level for the pilot channel and the datachannels is also higher. Therefore, there is an optimum pilot channelpower level with respect to a data channel power level for acommunication data rate at a decoding error rate performance level. Thefollowing graph may illustrate the pilot channel optimum power levelwith respect to the total power level used for transmission of the pilotchannel and the data channels.

The optimum pilot power level may be different for different data rates.Higher data rate transmissions have an optimum pilot level that may bemuch higher than the pilot level required for low data rates. Thedifference in optimal pilot levels for low and high data rates may beabout 13 dB.

The pilot channel power level is also measured by the receiver in apower control process for controlling the transmission power level.Typically, the receiver measures the signal to noise ratio (SNR) of thepilot channel. The measured SNR is compared to a threshold. If themeasured SNR is higher than the threshold, the receiver through itsaccompanying transmitter instructs the transmitting source to lower thepilot channel power. The data channel power level is also lowered tomaintain a pilot channel to data channel power level ratio. If themeasured SNR is lower than the threshold, the receiver through itsaccompanying transmitter instructs the transmitting source to increasethe pilot channel power. The data channel power level is also increasedto maintain a pilot channel to data channel power level ratio. As such,the receiving end through the power control process attempts to maintaina pilot SNR at the receiver for proper decoding process at a minimalerror rate.

The communication system also has a data rate control process thatattempts to maximize the transmission data rate for optimum datathroughput. Based on measured channel characteristics, the data rate maybe increased or lowered. In another aspect, the data rate may changebased on the demand, considering that the channel characteristics allowfor proper communications at the requested data rate.

In such a communication system, the pilot channel power control and thedata rate control may operate independently. As such, when the data rateis changed, the power level of the pilot channel may also change,without the power control process involvement, to maintain the optimumpilot channel power level. Since the power control process has noknowledge of the data rate change and the corresponding pilot channelpower change, the power control process may take the change in the pilotchannel power as a change in the channel propagation. Such a detectionnormally initiates a process for changing the pilot channel powerthrough the power control process. Therefore, if the change in the pilotchannel power level to satisfy a different data rate transmission iswithout notifying the receiving end in advance, the power controlprocess may erroneously instruct for the pilot channel to rectify itstransmit power.

Therefore, there is a need for power control process and data ratecontrol process to operate simultaneously in a communication systemwithout any adverse effect.

BRIEF DESCRIPTION OF THE DRAWINGS

The features, objects, and advantages of the present invention willbecome more apparent from the detailed description set forth below whentaken in conjunction with the drawings in which like referencecharacters identify correspondingly throughout and wherein:

FIG. 1 depicts a communication system for transmitting and receivingdata in accordance with various aspects of the invention;

FIG. 2 depicts a receiver system for receiving data in accordance withvarious aspects of the invention;

FIG. 3 depicts a transmitter system for transmitting data in accordancewith various aspects of the invention;

FIG. 4 depicts a flow diagram of one or more step at a transmitting endin accordance with various aspects of the invention;

FIG. 5 depicts a flow diagram of one or more step at a receiving end inaccordance with various aspects of the invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT(S)

A method and apparatus provides for efficient data rate control andpower control processes by transmitting a primary and a secondary pilotchannel associated with a data channel. The primary and secondary pilotchannels are used for decoding the data. A ratio of power levels of theprimary and secondary pilot channels is based on at least one of thedata rate and payload size of the data channel. The power level of theprimary pilot channel is maintained independent of at least one of datarate and payload size of the data channel. The power level of thesecondary pilot channel may be adjusted based on at least one of datarate and payload size of the data channel. One or more exemplaryembodiments described herein are set forth in the context of a digitalwireless data communication system. While use within this context isadvantageous, different embodiments of the invention may be incorporatedin different environments or configurations. In general, the varioussystems described herein may be formed using software-controlledprocessors, integrated circuits, or discrete logic. The data,instructions, commands, information, signals, symbols, and chips thatmay be referenced throughout the application are advantageouslyrepresented by voltages, currents, electromagnetic waves, magneticfields or particles, optical fields or particles, or a combinationthereof. In addition, the blocks shown in each block diagram mayrepresent hardware or method steps.

More specifically, various embodiments of the invention may beincorporated in a wireless communication system operating in accordancewith the code division multiple access (CDMA) technique which has beendisclosed and described in various standards published by theTelecommunication Industry Association (TIA) and other standardsorganizations. Such standards include the TIA/EIA-95 standard,TIA/EIA-IS-2000 standard, IMT-2000 standard, UMTS and WCDMA standard,all incorporated by reference herein. A system for communication of datais also detailed in the “TIA/EIA/IS-856 cdma2000 High Rate Packet DataAir Interface Specification,” incorporated by reference herein. A copyof the standards may be obtained by accessing the world wide web at theaddress: http://www.3qpp2.org, or by writing to TIA, Standards andTechnology Department, 2500 Wilson Boulevard, Arlington, Va. 22201,United States of America. The standard generally identified as UMTSstandard, incorporated by reference herein, may be obtained bycontacting 3GPP Support Office, 650 Route des Lucioles-Sophia Antipolis,Valbonne-France.

FIG. 1 illustrates a general block diagram of a communication system 100capable of operating in accordance with any of the code divisionmultiple access (CDMA) communication system standards whileincorporating various embodiments of the invention. Communication system100 may be for communications of voice, data or both. Generally,communication system 100 includes a base station 101 that providescommunication links between a number of mobile stations, such as mobilestations 102-104, and between the mobile stations 102-104 and a publicswitch telephone and data network 105. The mobile stations in FIG. 1 maybe referred to as data access terminals (AT) and the base station as adata access network (AN) without departing from the main scope andvarious advantages of the invention. Base station 101 may include anumber of components, such as a base station controller and a basetransceiver system. For simplicity, such components are not shown. Basestation 101 may be in communication with other base stations, forexample base station 160. A mobile switching center (not shown) maycontrol various operating aspects of the communication system 100 and inrelation to a back-haul 199 between network 105 and base stations 101and 160.

Base station 101 communicates with each mobile station that is in itscoverage area via a forward link signal transmitted from base station101. The forward link signals targeted for mobile stations 102-104 maybe summed to form a forward link signal 106. The forward link may carrya number of different forward link channels. Each of the mobile stations102-104 receiving forward link signal 106 decodes the forward linksignal 106 to extract the information that is targeted for its user.Base station 160 may also communicate with the mobile stations that arein its coverage area via a forward link signal transmitted from basestation 160. Mobile stations 102-104 may communicate with base stations101 and 160 via corresponding reverse links. Each reverse link ismaintained by a reverse link signal, such as reverse link signals107-109 for respectively mobile stations 102-104. The reverse linksignals 107-109, although may be targeted for one base station, may bereceived at other base stations.

Base stations 101 and 160 may be simultaneously communicating to acommon mobile station. For example, mobile station 102 may be in closeproximity of base stations 101 and 160, which can maintaincommunications with both base stations 101 and 160. On the forward link,base station 101 transmits on forward link signal 106, and base station160 on the forward link signal 161. On the reverse link, mobile station102 transmits on reverse link signal 107 to be received by both basestations 101 and 160. For transmitting a packet of data to mobilestation 102, one of the base stations 101 and 160 may be selected totransmit the packet of data to mobile station 102. On the reverse link,both base stations 101 and 160 may attempt to decode the traffic datatransmission from the mobile station 102. The data rate and power levelof the reverse and forward links may be maintained in accordance withthe channel condition between the base station and the mobile station inaccordance with various aspects of the invention.

FIG. 2 illustrates a block diagram of a receiver 200 used for processingand demodulating the received CDMA signal while operating in accordancewith various aspects of the invention. Receiver 200 may be used fordecoding the information on the reverse and forward links signals.Receiver 200 may be used for demodulating the pilot channel and decodinginformation on the data channels such as the fundamental channel,control channel and supplemental channels. Received (Rx) samples may bestored in RAM 204. Receive samples are generated by a radiofrequency/intermediate frequency (RF/IF) system 290 and an antennasystem 292. The RF/IF system 290 and antenna system 292 may include oneor more components for receiving multiple signals and RF/IF processingof the received signals for taking advantage of the receive diversitygain. Multiple received signals propagated through different propagationpaths may be from a common source. Antenna system 292 receives the RFsignals, and passes the RF signals to RF/IF system 290. RF/IF system 290may be any conventional RF/IF receiver. The received RF signals arefiltered, down-converted and digitized to form RX samples at base bandfrequencies. The samples are supplied to a multiplexer (mux) 252. Theoutput of mux 252 is supplied to a searcher unit 206 and finger elements208. A control system 210 is coupled thereto. A combiner 212 couples adecoder 214 to finger elements 208. Control system 210 may be amicroprocessor controlled by software, and may be located on the sameintegrated circuit or on a separate integrated circuit. The decodingfunction in decoder 214 may be in accordance with a turbo decoder or anyother suitable decoding algorithms. The signal transmitted from a sourcemay be encoded with several layers of codes. As such, the decoder 214decodes the received samples in accordance with such codes.

During operation, received samples are supplied to mux 252. Mux 252supplies the samples to searcher unit 206 and finger elements 208.Control unit 210 configures finger elements 208 to perform demodulationand despreading of the received signal at different time offsets basedon search results from searcher unit 206. The results of thedemodulation are combined and passed to decoder 214. Decoder 214 decodesthe data and outputs the decoded data. Despreading of the channels isperformed by multiplying the received samples with the complex conjugateof the PN sequence and assigned Walsh function at a single timinghypothesis and digitally filtering the resulting samples, often with anintegrate and dump accumulator circuit (not shown). Such a technique iscommonly known in the art. Receiver 200 may be used in a receiverportion of base stations 101 and 160 for processing the received reverselink signals from the mobile stations, and in a receiver portion of anyof the mobile stations for processing the received forward link signals.

The decoder 214 may accumulate the combined energy for detection of adata symbol. Each packet of data may carry a cyclic redundancy check(CRC) field. The decoder 214 may in connection with control system 210and or other control systems check for error in the received datapacket. If the CRC data does not pass, the received packet of data hasbeen received in error. The control system 210 and or other controlsystems may send a negative acknowledgment message to the transmitter toretransmit the packet of data.

FIG. 3 illustrates a block diagram of a transmitter 300 for transmittingthe reverse and forward link signals. The channel data for transmissionare input to a modulator 301 for modulation. The modulation may beaccording to any of the commonly known modulation techniques such asQAM, PSK or BPSK. Before modulation, the channel data for transmissionmay pass through one or more layers of coding. The channel data fortransmission are produced for modulator 301. The channel data fortransmission are received by the modulator 301.

The modulation data rate may be selected by a data rate and power levelselector 303. The data rate selection may be based on feedbackinformation received from a destination. The data rate very often isbased on the channel condition, among other considered factors. Thechannel condition may change from time to time. The data rate selectionmay also change from time to time.

The data rate and power level selector 303 accordingly selects the datarate in modulator 301. The output of modulator 301 passes through asignal spreading operation and amplified in a block 302 for transmissionfrom an antenna 304. The data rate and power level selector 303 alsoselects a power level for the amplification level of the transmittedsignal. The combination of the selected data rate and the power levelallows proper decoding of the transmitted data at the receivingdestination. A pilot signal is also generated in a block 307. The pilotsignal is amplified to an appropriate level in block 307. The pilotsignal power level may be in accordance with the channel condition atthe receiving destination. The pilot signal may be combined with thechannel signal in a combiner 308. The combined signal may be amplifiedin an amplifier 309 and transmitted from antenna 304. The antenna 304may be in any number of combinations including antenna arrays andmultiple input multiple output configurations.

Referring to FIG. 4, a flow diagram 400 depicts one or more step at atransmitting end in accordance with various aspects of the invention.The transmitting end, in case of reverse link in communication system100, may be the mobile stations, and the transmitter may be thetransmitter 300. In accordance with various aspects of the invention,the problem with contention of data rate and power control processes isresolved by transmission and use of multiple (more than one) pilotchannels. The mobile stations transmit more than one pilot channelassociated with a reverse link. In one embodiment, the mobile stationstransmit two pilot channels associated with transmission of a datachannel. At step 401, the mobile station determines the data rate of thedata channel for transmission to a receiving end such as the basestation 101 or 160. The data rate may be determined based on commonlyknown processes. Such processes include determining the data rate basedon the propagation channel characteristics or a requested data rate. Thetransmission data rates may range from a low value to a high value. Thestandard defining the operating requirements of communication system 100may define the range. At step 402, the determined data rate is comparedto a predetermined value. For example, the predetermined value may be adata rate between 38,400 bits/sec and 115,200 bits/sec. At step 403, ifthe determined data rate is higher than the predetermined value, themobile station transmits a primary pilot channel and a secondary pilotchannel in accordance with various aspects of the invention. The powerlevel of the primary pilot channel is determined independent of thedetermined data rate. The power level of the primary pilot channel isgenerally determined in accordance with the power control process;however, in accordance with an embodiment, the power level does notchange with respect to the determined data rate. The secondary pilotchannel is transmitted at a power level higher than the primary pilotchannel power level in accordance with various aspects of the invention.The power level of the secondary pilot channel may be 19 times higherthan the primary pilot channel power level.

Generally, the system may allow for transmissions of data at a number ofdifferent data rates. The number of data rates below the predeterminedvalue may be more than one. The number of data rates above thepredetermined value may also be more than one. In one exemplaryembodiment, the rates above the predetermined value are 115,200 bits/s,230,400 bits/s, and 307,200 bits/s, while the rates below thepredetermined value are 9,600 bits/s, 19,200 bits/s, and 38,400 bits/s.

The data rates values may be replaced by payload size values, or anyother parameter that its value indicates a relationship in at least oneaspect to the data rate of data transmission. Therefore, thepredetermined value relates to such values of such parameters. In oneexemplary embodiment the system may use hybrid automatic re-transmission(HARQ). In such a case, the data rates may not be clearly defined sincethe data rate depends on the number of frame transmissions the datapacket may require for completing the transmission from a transmittingend and proper reception at a receiving end. In such a system, thepredetermined value may be a payload size of a frame or a time slot. Thepayload sizes may include 192, 384, 768, 1536, 3072, 4608, and 6144bits. Payload sizes 192, 384, 768, and 1536 bits may be below thepredetermined value. Therefore, any transmission of data at such payloadsizes is transmitted without a secondary pilot. The payload sizes 3072,4608, and 6144 bits may be above the predetermined value. Therefore, anytransmission of data at such payload sizes is transmitted with asecondary pilot.

In accordance with various aspects of the invention, the power level ofthe primary pilot channel does not change with data rate. Accordingly,even though for data rates below the predetermined value when thesecondary pilot channel is not transmitted, the primary pilot channelpower level is independent of the communication data rates. Inaccordance with various aspects of the invention, the power levels ofthe primary and secondary pilot channels for data rates above thepredetermined value remain independent of the data rates. The powerlevels of the primary and secondary pilot channels, in one embodiment,remain at the same ratio for all data rates above the predeterminedvalue.

Referring to FIG. 5, a process flow 500 for receiving and decoding adata channel is outlined in accordance with various aspects of theinvention. At step 501, the receiver may receive a primary pilotchannel. The receiver may be a base station in the communication system100. The receiver may be the receiver 200 shown in FIG. 2. At step 502,the receiver determines whether the received primary pilot channel istransmitted with a secondary pilot channel. Such a detection may beperformed by searching for an energy level of the secondary pilotchannel above an energy threshold, or above the energy level of theprimary pilot channel. Since the secondary pilot channel is transmittedat a much higher level, the detection of such an energy level may easilybe accomplished by the receiver 200 very quickly, e.g. one slot of 1.25ms. If the secondary pilot channel is detected, at step 503, thereceiver 200 may combine the primary and secondary pilot channels toimprove the phase and amplitude estimate for multi-path combining of theother channels such as the data channels in receiver structure 200.Those skilled in the art appreciate that the improved phase andamplitude reference also aids other types of receivers such asequalizers. Those skilled in the art may further appreciate that theability to rapidly detect the presence of the secondary pilot and itslevel relative to the primary pilot is of a great benefit forimplementation, since it directly reduces the amount of memory necessaryin the receiver for buffering the signal before multi-path combining. Inreceiver 200, such additional memory requirement would have increasedthe size of sample RAM 204 or added into the front of each fingerelement 208, and thus increasing their complexity.

When the primary pilot is transmitted without the secondary pilotchannel, the SNR estimation for power control may be based on theprimary pilot channel received signal. When the primary pilot istransmitted with the secondary pilot channel, the SNR estimation may bebased on the secondary pilot channel received signal since the secondarypilot channel may be transmitted at higher signal level than the primarychannel. The combination of the primary and secondary pilot channelsdetermined at step 503 may also be used to generate a more accurate SNRestimate of the propagation channel for power control. The SNR values ofthe primary and secondary pilot channels may be combined in accordancewith a weighted combining process. For example, more weight is accordedthe SNR value of the secondary pilot channel than the primary pilotchannel since the secondary pilot channel may be transmitted at highersignal level than the primary channel.

The performance of the power control process is also improved based onan improved SNR determined at step 503. An inaccurate SNR estimatedegrades the power control performance by leading inaccuracy incontrolling the receiver power to the desired value. For power controlprocess, the improved estimate of the SNR value is compared to a powercontrol threshold. If the SNR is higher than the threshold, thereceiving end instructs the transmitting to lower the transmission powerlevel. If the SNR is lower than the threshold, the receiving endinstructs the transmitting to increase the transmission power level. Inaccordance with various aspects of the invention, the power controlprocess at the transmitting end adjusts the primary pilot channel powerlevel in response to the power control command. The secondary pilotchannel power level is based in accordance with various aspects of theinvention on a predetermined ratio with respect to the primary pilotchannel power level. Therefore, when the primary pilot channel powerlevel changes in response to the power control command, the secondarypilot channel power level also changes correspondingly; however, thepower level ratio remains the same.

A delayed SNR estimate may also degrade the power control process whenthe channel is varying over time. Typically, the delay in estimating theSNR for power control is 1 time slot. Since the time necessary to detectthe presence of a secondary pilot may also be one time slot, the primaryand secondary pilots may be combined without significantly increasingthe latency in the SNR estimation. The power control therefore stillfunctions well when the channel is varying over time.

The transmitting end may also have sent a rate indicator channel (RICH)along with transmission of data on the data channel. The receiving endat step 504 receives the RICH. The RICH is used to assists the receivingend to determine the data rate of data channel. The determined data rateis used in the decoding process of the data channel. As such, in orderto correctly and accurately decode the data channel, the informationobtained from the RICH needs to be accurate. Generally, for decoding theRICH, the receiver makes several hypotheses about the received data onthe RICH. At the end, the receiver picks one of the hypotheses with thehighest confidence level. Since the receiver needs to examine severalhypotheses, detection of the secondary pilot channel may help thereceiver decode the RICH. As such, at step 505, the receiver decodes theRICH based on at least a hypothesis that the indication of thetransmitted data rate corresponds to a data rate higher than thepredetermined value used in the transmitter to trigger transmission ofthe secondary pilot channel. In one aspect, the receiver may ignore anyoutcome of the RICH decoding process that corresponds to data rate lowerthan the predetermined data rate. Similarly, if the secondary pilot isnot detected, the data rate is most likely below the predetermined valuethat is used to trigger transmission of the secondary pilot channel. Atthe step 506, the receiver decodes the data channel based on the decodedRICH. The decoding process may involve multi-path combining anddemodulation processes. The estimate of the improved phase and amplitudereference determined at step 503 may be used for the decoding process atstep 506.

In other aspects, the RICH may be required to carry less information ifthe transmission of the secondary pilot channel is used in accordancewith various aspects of the invention. When less information needs to betransmitted, the performance of the decoding process may be improved.For example, instead of the RICH allowing 32 possible inputs for thefour sub-packet identifiers and eight possible encoder packet sizes orallowing 33 possible inputs with an additional zero-rate indicatorinput, the transmission and detection of the secondary pilot channel maybe used to reduce the amount of data indicating the number of encoderpacket sizes that is possibly transmitted. The rate indicator processthrough the RICH may reduce the number of possible inputs to 16 (or 17with a zero-rate indicator) by using a secondary pilot channel detectionto specify which of the four largest of eight encoder packet sizes isused and the lack of a secondary pilot detection to specify which of thesmallest four encoder packet sizes is used. In one exemplary embodiment,the encoder packet sizes may be 192 bits, and 384 bits. The sub-packetidentifiers may be ‘0’, and ‘1’. The RICH may therefore contain any of 4code-words corresponding to an encoder packet size and a sub-packetidentifier. The RICH code-words may be “00”, “001”, “10”, and “11”. Ifthe presence of the secondary pilot is used to deduce the payload size,then the RICH may use only 2 code-words, for example “00”, and “01”.

In another embodiment, the power level of the secondary pilot channelmay be selected to be higher than the primary pilot channel inaccordance with a number of predefined ratios. For example, if the datarate of the data channel is above a first predetermined value but belowa second predetermined value, the power level of the secondary pilotchannel is higher than the primary pilot channel in accordance with afirst defined ratio. Furthermore, if the data rate of the data channelis above the second predetermined value, the power level of thesecondary pilot channel is higher than the primary pilot channel inaccordance with a second defined ratio. On the receiving end, afterdetecting the primary pilot channel, the power level of the secondarypilot channel may determine the range of the expected values of decodingthe RICH. If the received power level ratio of the primary and secondarypilot channels corresponds to the first ratio, the expected value ofdecoding RICH would be between the first and second predeterminedvalues. If the received power level ratio of the primary and secondarypilot channels corresponds to the second ratio, the expected value ofdecoding RICH would be above the second predetermined value.

The selection of optimum total pilot channels power level may bedescribed by the following graphs.

For data rates R4, R5 and R6, the combined primary and secondary pilotchannels power level is selected such that the total power levelcorresponds to an optimum power level nearly suitable for R4, R5 and R6data rates. For data rates R1, R2 and R3, the pilot power level consistsof the power level of the primary pilot channel. Similarly, the totalpilot power is selected such that the power level is nearly suitable fordata rates R1, R2 and R3. The predetermined value that establisheswhether to transmit a secondary pilot channel is based between R3 and R4values. As such, the pilot channel power level is selected near anoptimum level while allowing the data rate control and power controlprocesses to operate together without any contention between the needsto transmit a higher pilot power level for high data rates and powercontrol based on the received pilot channel SNR.

Those of skill in the art would further appreciate that the variousillustrative logical blocks, modules, circuits, and algorithm stepsdescribed in connection with the embodiments disclosed herein may beimplemented as electronic hardware, computer software, or combinationsof both. To clearly illustrate this interchangeability of hardware andsoftware, various illustrative components, blocks, modules, circuits,and steps have been described above generally in terms of theirfunctionality. Whether such functionality is implemented as hardware orsoftware depends upon the particular application and design constraintsimposed on the overall system. Skilled artisans may implement thedescribed functionality in varying ways for each particular application,but such implementation decisions should not be interpreted as causing adeparture from the scope of the present invention.

The various illustrative logical blocks, modules, and circuits describedin connection with the embodiments disclosed herein may be implementedor performed with a general purpose processor, a digital signalprocessor (DSP), an application specific integrated circuit (ASIC), afield programmable gate array (FPGA) or other programmable logic device,discrete gate or transistor logic, discrete hardware components, or anycombination thereof designed to perform the functions described herein.A general-purpose processor may be a microprocessor, but in thealternative, the processor may be any conventional processor,controller, microcontroller, or state machine. A processor may also beimplemented as a combination of computing devices, e.g., a combinationof a DSP and a microprocessor, a plurality of microprocessors, one ormore microprocessors in conjunction with a DSP core, or any other suchconfiguration.

The steps of a method or algorithm described in connection with theembodiments disclosed herein may be embodied directly in hardware, in asoftware module executed by a processor, or in a combination. A softwaremodule may reside in RAM memory, flash memory, ROM memory, EPROM memory,EEPROM memory, registers, hard disk, a removable disk, a CD-ROM, or anyother form of storage medium known in the art. An exemplary storagemedium is coupled to the processor such that the processor can readinformation from, and write information to, the storage medium. In thealternative, the storage medium may be integral to the processor. Theprocessor and the storage medium may reside in an ASIC. The ASIC mayreside in a user terminal. In the alternative, the processor and thestorage medium may reside as discrete components in a user terminal.

The previous description of the preferred embodiments is provided toenable any person skilled in the art to make or use the presentinvention. The various modifications to these embodiments will bereadily apparent to those skilled in the art, and the generic principlesdefined herein may be applied to other embodiments without the use ofthe inventive faculty. Thus, the present invention is not intended to belimited to the embodiments shown herein but is to be accorded the widestscope consistent with the principles and novel features disclosedherein.

1. A method for a communication system, comprising: determining at leastone of data rate and payload size of a data channel in a reverse linkcommunication; comparing at least one of said determined data rate andpayload size to a predetermined value; determining whether transmissionof a primary pilot channel associated with said data channel and asecondary pilot channel associated with said data channel are necessarybased on said comparing; transmitting the primary pilot channel and thesecondary pilot channel; and transmitting data on said data channel. 2.The method as recited in claim 1, further comprising: determining aratio of power levels of said primary and secondary pilot channels basedon at least one of said determined data rate and payload size.
 3. Themethod as recited in claim 1, further comprising: maintaining powerlevel of said primary pilot channel independent of at least one of datarate and payload size of said data channel.
 4. The method as recited inclaim 1, further comprising: adjusting power level of said secondarypilot channel based on at least one of data rate and payload size ofsaid data channel.
 5. The method as recited in claim 1, furthercomprising: receiving said primary, secondary pilot and data channels;and decoding said data on said received data channel based on channelinformation determined from said received primary and secondary pilotchannels.
 6. An apparatus for a communication system, comprising: acontroller configured for: determining at least one of data rate andpayload size of a data channel in a reverse link communication;comparing at least one of said determined data rate and payload size toa predetermined value; and determining whether transmission of a primarypilot channel associated with a data channel and a secondary pilotchannel associated with said data channel are necessary based on saidcomparing; and a transmitter configured for: transmitting the primarypilot channel, the secondary pilot channel and data on said datachannel.
 7. The apparatus as recited in claim 7, wherein said controlleris further configured for: determining a ratio of power levels of saidprimary and secondary pilot channels based on at least one of saiddetermined data rate and payload size.
 8. The apparatus as recited inclaim 6, further comprising: a power control processor for maintainingpower level of said primary pilot channel independent of at least one ofdata rate and payload size of said transmitting data on said datachannel.
 9. The apparatus as recited in claim 6, further comprising: apower control processor for adjusting power level of said secondarypilot channel based on at least one of data rate and payload size ofsaid data channel.